DE2431224C3 - Vacuum interrupter or circuit breaker - Google Patents

Description

ίο The invention relates to a vacuum interrupter or circuit breaker with a vacuum housing, two current-carrying rods led out of the housing under an airtight seal, which can be connected to an external electrical current path, two electrode units each attached to the front end of the current-carrying rods, the electrode surfaces of which face one another sir.d arranged opposite one another and each having a main electrode, at least e ^; ne of the electrode units can be moved into and out of contact with the other electrode unit by means of an actuating device, so that an electrical current flow is enabled or interrupted, and with an excitation coil attached to at least one electrode unit, consisting of several excitation coil units, which are close to each other in a practically parallel to Surface of the main electrode lying plane and are connected at one end to the conductive rod and at the other end to the main electrode.

When an electrical current flows through a vacuum interrupter it generally becomes two Main electrodes kept in contact with each other. If the main electrodes are replaced by a suitable Actuating device are moved apart, an arc occurs between them, the is sustained by a plasma emitted from the cathode. Usually this will occur of the plasma is interrupted at the point in time when the electric current drops to zero.

As a result, the arc can no longer be maintained, so that the electric current is interrupted. But if the device is traversed by a large electric current, an intense arc occurs. The resulting magnetic field, which is created by the Arc itself generated magnetic field as well as from other circuits, z. B. from the external lines, to which the two current-carrying rods are connected, results in generated magnetic fields the arc itself, so that it becomes unstable. As a result, the arc is concentrated on or in the outer circumference of the electrode surface Proximity, causing the electrode area in question to be locally overheated and emitting a large amount of plasma.

As a result, the vacuum prevailing in the housing is reduced and consequently the interruptibility is impaired.

Attempts have already been made to avoid these disadvantages

has been used to enlarge the surface area of a main electrode and thereby lowering the density of the electric current, or in the surface of the Main electrode to provide spiral incisions to displace the arc along the spiral groove outward allow. In the former case, however, there is always nor the possibility of the arc coming on the circumferential surface of the main electrode, while the arc is not in the latter case evenly over the entire area of the main electrode can be distributed. In any case it is impossible generate a stable, evenly distributed arc.

If the plasma escapes from the area between the main electrodes and no for the stable maintenance of the arc sufficient plasma is achieved, the surface of the Main electrode locally overheated, which leads to a localized fusion. If that is between If the plasma present in the main electrodes escapes, the arc voltage increases and is maintained of the electric current. Since in this case a If a larger amount of energy is applied to the main electrode, the latter experiences local overheating with it resulting from local amalgamation.

To avoid this condition, it is known to apply a magnetic field perpendicular to the surface of the main electrode to put on. It is believed that electrodes, neutral atoms and ionized atoms are all rolled into one Ratio of about 100: 10: 1 emitted from a cathode spot of the arc, being mainly the electrons and ionized atoms serve to maintain an arc. At a A magnetic field applied perpendicular to the surface of the main electrode causes the electrons to move along it Including the magnetic field, it tiate an outward distribution from the area between the electrodes.

When the electrons are thus confined between the main electrodes, the number of becomes out the area between the main electrodes is reduced electrons escaping, so that the arc is stabilized. The movement of the electrons extends their path to the anode Movement of the electrons towards the anode increases the likelihood that the electrons will have a Cause ionization of neutral atoms and thereby amplify an insufficient plasma and the Stabilize the arc. The magnetic field also acts on the ionized atoms in such a way that they interweave the electrodes. In this way the arc is under the influence of the magnetic field set or trapped between the electrodes.

An excitation coil is used to apply a magnetic field perpendicular to the surface of the main electrode arranged around the outer circumference of a vacuum housing and connected to the main electrode current-carrying rod connected, or part of the current-carrying rod can be inside the vacuum housing wound in the form of a coil and connected to the main electrode. In the first mentioned However, it is difficult to obtain a magnetic field that exhibits a sufficient effect because the The excitation coil and the electrode are far apart. There is also a fairly large excitation coil required, which leads to a complex, sDerrieen and heavy vacuum interrupter.

In the / far-mentioned case, the construction of the current-carrying rod is complicated, so that it is difficult is to be established. In addition, the internal structure becomes complicated, so that the vacuum interrupter as a whole together becomes heavy and large.

The invention is therefore primarily the task based on creating a vacuum interrupter or circuit breaker with a high interruption capacity by appearing between the main electrodes

ίο Arc uniform and stable over the surface Chen of the main electrodes is distributed.

This vacuum interrupter or protection switch should also be a small, compact one in a vacuum housing designed excitation coil, which eir magnetic field perpendicular to the surface of each main electrode capable of generating so that an arc generated between the main electrodes is uniform and is stably distributed over their surfaces.

This task is performed with a vacuum breaker or circuit breaker of the type mentioned at the beginning solved according to the invention in that the Eerregerspu-Ie has a plurality of first arms which are parallel to the upper surface of the main electrode and radially to the current-carrying Rod are connected to the latter and extend at a mutual angular distance furthermore a plurality of second arms connected to the main electrode and which are close to the respective first arms are arranged and extend parallel to them with an overlap, as well as several arc-shaped Sections which, with a single material connection, arcuate from the front end of each first Arm to the front end of the next second arm until close to the next first arm, so that the magnetomotive forces are soft flowing through the first and second arms electrical branch currents are generated, practically cancel each other out and through which the respective Arc sections flowing through branch electrical currents perpendicular to the surface of the main electrode running magnetic fields are generated.

The magnetic fields generated by the individual excitation coils act on the surface of the main electrode as a magnetic field covering the entire surface of the main electrode. The respective Magnetic fields not only prevent an exit or escape of the arc by enclosing a Plasma to maintain the arc that occurs between the main electrodes, rather They also cause the electrons present in the plasma to shift to an anode, whereby a There is a possibility that neutral atoms are ionized by the electrons, which causes plasma formation is favored. As a result, the arc is stabilized and uniform over the surface distributed around the main electrode. According to the invention, a vacuum interrupter or circuit breaker is thus provided high interruption performance, that means no overheating or thermal welding as a result the concentration of the arc on or in the vicinity of the peripheral surface of the main electrode Circumferential surface occurs.

By increasing or decreasing the number of excitation coil units, the strength of the over the total area of the excitation coil assembly away generated magnetic field increased or decreased accordingly will. When the magnetic field generated across the electrode surface is adjusted to be Value close to that for the power interruption

The most appropriate value can be a vacuum interrupter can be ensured with high interruption performance without the device becoming too large. The magnetic field of the excitation coil is practically the same as a magnetic field that is generated by that an electric branch current flowing through each excitation coil unit through an imaginary coil is passed through with a turn, the sections obtained by connecting the arc concerned will.

If a contact is attached to the front end of the main electrode, which has a comparatively high contact Has vapor pressure and is difficult to weld. will close the arc on the contact a zero point of the arc current is concentrated, and the arc can be under the influence of a magnetic field be distributed practically evenly over the contact surface.

When a plurality of curved slits are provided in the main electrode close to the center of the If the main electrode go out and open on their outer circumference, the arc will shift along these slots in an outward direction, one being attached to the main electrode by the magnetic field of the excitation coil generated leakage current is reduced. As a result, the arc can be further stabilized and as a result the presence of the contact as well as under the influence of the magnetic field are distributed more evenly. If a magnetic field generated by the excitation coil 'is comparatively weak on the central area of the Contact acts and the arc is localized in this egg area. becomes in the middle area of the contact a through hole is provided to prevent a local concentration of the arc.

The following are embodiments of the invention explained on the basis of the drawing. It shows

F i g. 1 is a sectional side view showing the construction of a vacuum interrupter or circuit breaker with features according to the invention.

F i g. 2 is a sectional view, on an enlarged scale, of a vacuum interrupter according to the invention used electrode unit.

F i g. 3 is a perspective view of the electrode unit.

F i g. Fig. 4 is a plan view of a main electrode provided with contact in which a plurality of slits are formed are.

F i g. 5 is a side view of the main electrode according to FIG. 4th

F i g. 6 shows a plan view of a main electrode similar to the electrode according to FIG. 4, the contact of which with a through hole is provided. and

F i g. 7 shows a side view of the main electrode according to FIG . 6th

F i g. 1 is an explanatory diagram schematically illustrating the structure of a vacuum interrupter according to an embodiment of the invention. A vacuum housing of the device has a cylindrical insulating body 12 closed by end caps 14 and 16. The housing 10 contains two similar electrode units 13, 20 which are arranged opposite one another. These electrode units 18 and 20 are each mounted on the ends of current-carrying rods 22 and 24, respectively. The rod 24 and therefore the electrode unit 20 can be moved back and forth up and down by an actuating unit (not shown). The vacuum interrupter is closed or opened by the upward or downward movement of the current-carrying rod 24. A bellows 26 is provided to enable the current-carrying rod 24 to move up and down with an airtight seal. The electrode units 18 and 20 are enclosed by a shield 28.

The electrode unit 18 has a main electrode

ίο 30 and an excitation coil 34 while the electrode unit 20 has a main electrode 32 and an excitation coil 36. When the electrode units 18 and 20 are in contact with each other, is the vacuum interrupter closed or switched through, so that a main electrical current is the current-carrying Rod 22, the electrode unit 18, the electrode unit 20 and the current-carrying rod 24 flow through can. In order to interrupt the main flow of current, one current-carrying rod and the associated one are switched on the electrode unit mounted to him is moved away from the other rod along with its associated electrode unit, so that the main electrodes 30 and 32 are spaced apart from each other. The main stream flows through the Excitation coils 34 and 36 and erze.igt in them a magnetic field perpendicular to the surface of the main electrodes 30 and 32.

F i g. 2 is a sectional view of the most energized Rod 22 attached electrode unit 18. The electrode unit 20 is constructed identically, so that in the following only the electrode unit 18 needs to be explained in more detail.

Fig. 3 illustrates! the excitation coil 34 and the Main electrode 30 of the electrode unit 18 to facilitate understanding of the space in between between the excitation coil 34 and the main electrode shown in exaggerated size.

According to FIG. 2 has the electrode unit 18 (the excitation coil 34 and the main electrode 30. A contact 38 is provided on the main electrode 30.

but which can also be omitted if the power interruption requirements permit. The excitation coil 34 has first and second coil conductors 40 and 42, respectively, and an intermediate member 44 and a connecting conductor 46 arranged between the two coil conductors 40 and 42. which the two Coil conductors 40 and 42 connects to one another at a distance from one another.

When the current-carrying rod 22 is traversed by the main electrical current, this current flows from the rod 22 via the first coil conductor 40. the connecting conductor 46 and the second coil conductor 42 to the main electrode 30 and then directly or via an arc to the other main electrode 32 Excitation coil 34

flowing through is due to the magnetomotive The force of the electric current generates a magnetic field perpendicular to the surface of the main electrode 30. That between the two Spulenkitern 40 and 42 arranged: intermediate member 44 serves to this at

to hold the coil conductor r in its center in an electrically separated, but mechanically connected state.

In the case of the in F ii g. 3, the first coil 34 has a first central conductor 48, which is placed on the current-carrying rod 22, from which four arms 50, each with the same length, extend radially into a plane perpendicular to the rod 22, where

5

24 p

From the front end of each of these arms an arc of a circle Section 54 goes off in the direction of the front end of the adjacent arm, so that this section describes an arc and between its free end and the front end of the neighboring one Arms defines an appropriate air gap. The first arch sections 54 each extend from the front end of the associated arm in the same direction. According to FIG. 3 run the arc sections 54, seen from above, clockwise. The second coil liter 42 is at its center with a second central conductor 56 is provided, which is connected to the first central conductor 48 via the intermediate member 44 is. The intermediate member 44 is usually made of a high strength metal, e.g. B. made of stainless Steel. The intermediate member 44 can also consist of a rigid insulating material. From the second central Ladder 5fi go from four further arms 58, which overlap the first arms 50 at a distance therefrom and the length of which corresponds to that of the first arms 50. From the front ends of the two-tone arms 58, second arcuate sections 62 each extend - from the top of FIG. 3 seen - opposite clockwise with overlap by the first arcuate sections 54 at a distance from these parallel to them, each between the free end of the bow section and the front end of the associated second arm an appropriate air gap 60 is set. The first and second arch sections 54 or 62 as well as the connecting conductor 46 / between them are connected to one another in a uniform manner, so that they are conductive.

The main electrode 30, at the end of which if desired one contact. 38 is attached to the second coil conductor 42.

In the following the case will now be considered in which an electric current flow by moving the main electrode unit 20 on the main electrode unit 18 is interrupted.

When the main electrode unit 20 is displaced away from the main electrode unit 1 «by means of an actuating device (not shown), an arc is created between the main electrode ″ 30 and 32. The arc current flow from the current-carrying rod 22 to the current-carrying rod 24 is shown below with reference to FIG The arc current flows from the rod 22 into the first central conductor 48, from where it, as indicated by the arrow A , flows through the first four branches, ie branches in four directions the arrows A. B, C. D and E indicated way by an excitation coil unit 64 with one turn, which consists of the first arm 50, the first arc section 54, the connecting conductor 46, the second arc section 62 and the second arm 58, whereupon the current arrives at the second central conductor 56 and jumps from the main electrode 30 via an arc to the other electrode unit 20. Each from the branch current du The flowing electrical current path usually consists of a material of low resistance, for example copper or a copper alloy. In contrast, the intermediate member 44 is made of a high resistance material. As a result, only a small portion of the current flows via the intermediate member 44, while the majority of the current flows via the excitation coil unit 64.

In an excitation coil unit 66 arranged next to the coil unit 64, the branch current flows into the

by the arrows F, C, H,! and / direction indicated, wherein a magnetic field is generated in the same direction as that of the exciting coil unit 64.

All coil units of the excitation coil 34 thus generate a perpendicular to the surface of the main electrode 30 moving magnetic field. Since each excitation coil unit is first and second, mutually overlapping Arms 50 and 58, respectively, lift the magnetomotive generated at the first and second arms Powers! practically on, while those on the four conductive arc sections, each consisting of the arc sections 54 and 62 as well as the connection lciter 46 exist, generated magnetomotive forces for Contribute generation of said magnetic field. The magnetic field of the excitation coil 34 corresponds practically a magnetic field generated when a branch current flowing through each excitation coil unit is passed through an imaginary coil with a single turn, which by interconnection of the respective arc sections is obtained.

An excitation coil 34 is provided both on the electrode unit 18 and on the electrode unit 20. However, if a weak magnetic field is allowed. the excitation coil will only be on one of the two Electrode units 18 or 20 are provided.

According to FIG. 3, the excitation coil 34 consists of four excitation coil units 64 and 66. When the excitation coil units are provided in numbers of 2, 3, 6 ... π, the amount flowing through each coil unit reaches Branch stream 1/2, 1/3. 1/6 ... 1 / n of the arc current, while the induced magnetic field has an intensity corresponding to 4/2. 4/3, 4/6 ... 4 / n compared to the intensity in the arrangement according to FIG. 3 generated Reached the magnetic field. The cross-sectional area of the individual excitation coil units 64 and 66 is dependent chosen according to the size of the branch stream. The strength of the magnetic field can be through Formation of the excitation coil 34 can be varied in the manner mentioned above.

According to FIGS. 4 and 5, the main electrode 30 is penetrated by spirally extending slots. When a contact 38 is provided on the main electrode. these spiral slits are pierced in such a way that they extend through the main electrode 30 and the contact 38 as shown in FIG. The spiral contactor allows the arc to be displaced along its length, and it limits an eddy or stray current generated at the main electrode 30 by the magnetic field of the excitation coil, so that an appropriate axial magnetic field is induced through which the arc is practically uniform over the surface the main electrode 30 is distributed away, whereby local overheating or welding of the main electrode is prevented. An experiment has shown that when the main electrodes 30 and 32 move apart, the arc is distributed over the entire surface of the main electrode 30 within a few milliseconds.

The contact 38 is, for example, from a ternary ren alloy of Cu, Te and Se produced in Compared to the main electrode 30 a relatively large has high vapor pressure and is difficult to weld. The contact 38 ensures that the arcing on its surface at a point near the zero point: the arc current arises where the arcing occurs under the influence of the magnetic field generated by the excitation coil 34 evenly over the surface

609637/30

of contact 38 is distributed. In this way the arc is stabilized while the surface of the Main electrode 30 does not experience any local damage.

If according to FIGS. 6 and 7 a through hole 70 is provided in the center of the contact 38, local overheating or welding of the main electrode 30 in its central area can be prevented will. Since the contact 38 is made of a highly flammable material! relates ur "to its center the through hole is sunk, becomes a concentration of the arc in the central area of the contact 38, where the magnetic field of the excitation coil Ie 34 is weak.

An even better effect is achieved if the entire main electrode 30 is on the one for the contact 38 material used. However, the material for contact 38 is usually hard and brittle and difficult to machine, and contact 38 has size limitations and subject to form. For this reason, a contact 38 of the appropriate size is preferably used attached to the end face of the main electrode 30. If the size and shape of the main electrode 30 permit, may but these can also be made of the same material as the contact 38.

As mentioned, in the vacuum interrupter according to the invention, a small, powerful excitation coil 34 is off a plurality of excitation coil units 64, 66 arranged behind at least two main electrodes 30 and 32 whereby a magnetic field of suitable magnitude perpendicular to the surface of the main electrodes 30 and 32 is generated without making the vacuum interrupter heavy and large. The magnetic field does not prevent only an escape of the plasma forming the arc from the area between the main electrodes 30 and 32, if these are moved apart, it also favors plasma formation and stabilization of the arc so that the arc is evenly distributed over the surface of the main electrodes 30 and 32 is distributed. The surface of the main electrode is thus against local overheating or welding as a result of an uneven distribution of the arc or an excessively high local concentration Arc protected, which improves the interruption capacity of the vacuum interrupter will. The even distribution as well as the stabilization of the arc is continued by the Attachment of the contact 38 to the surface of the main electrodes 30 and 32, by the arrangement of the spiral slots perpendicular to the surface of the main electrodes 30 and 32 as well as through the arrangement the through hole 70 in the center of the contact 38 is favored. Through the interaction of these Measures a vacuum interrupter with high interruption capacity is guaranteed.

For this purpose 2 sheets of drawings

Claims (5)

Patent claims: 1. Vacuum interrupter or circuit breaker with a vacuum housing, two under airtight Sealing led out of the vacuum housing, current-carrying rods which can be connected to an external electrical current path, two each electrode assemblies attached to the front end of the current-carrying rod concerned. whose electrode surfaces are arranged opposite one another, and each have a main electrode have, wherein at least one of the electrode units by means of an actuating device is displaceable in and out of contact with the other electrode unit so that an electrical Current flow enabled or interrupted, and with at least one electrode unit attached excitation coil, consisting of several excitation coil units, which are close to each other arranged in a plane lying practically parallel to the surface of the main electrode and connected at one end to the conductive rod and at the other end to the main electrode are, characterized in that the excitation coil (64, 66) has a plurality of first arms (50), which are parallel to the surface of the main electrode (30, 32) and radially to the current-carrying rod (22. 24) are continuously connected to the latter and extend at a mutual angular distance, furthermore a plurality of second arms (58) connected to the main electrode (30. 32), which are close to the respective first arms (50) are arranged and extend parallel to them with an overlap as well as several circular arc-shaped sections (54, 46, 62), which under material uniform Connection in an arc shape from the front end of each first arm (50) to the front end of the next second arm (58) to run close to the next first arm (50) so that the magnetomotive forces flowing through the first and second arms (50 and 58, respectively) electrical branch currents are generated, practically cancel each other out and through which the respective Arch sections (54, 46, 62) flowing through electrical branch currents perpendicular to the surface of the Main electrode (30, 32) running magnetic fields are generated. 2. Vacuum interrupter according to claim 1, characterized in that the various arc sections (54,46, 62) each by a first arcuate section (54) which is arcuate from the front end of the first arm (50) extends in one direction towards the front end of the next first arm (50) and between the free end of the relevant first arc section (54) and the The front end of the next arm (50) defines a gap (52), a second arcuate section which is arcuate opposite to the first arch portion (54) from the front end of the second arm (58) to the front end of the adjacent second arm (58) and thereby between the free end of the relevant arch section (62) and the free end of the adjacent second arm (58) defines a gap (60), and a connecting conductor (46) is formed, each between a first and a second arc section (54 or 62) is arranged and electrically connected to this. 3. Vacuum interrupter according to claim 1, characterized in that on the end face of the Main electrode (30, 32) a contact (38) is attached. 4. Vacuum interrupter according to claim 3, characterized in that the main electrode (30, 32) has several curved slits (68) passing through it, which are close to the center of the main electrode (30, 32) go out and open on their peripheral surface. 5. Vacuum interrupter according to claim 4, characterized in that the contact (38) in his Center with a through hole (70) to prevent localized concentration the arc is provided.